Vinita Lukose scite author profile

Polyprenol phosphate phosphoglycosyl transferases (PGTs) catalyze the first membrane-committed step in assembly of essential glycoconjugates. Currently there is no structure-function information to describe how monotopic PGTs coordinate the reaction between membrane-embedded and soluble substrates. We describe the structure and mode of membrane association of PglC, a PGT from Campylobacter concisus. The structure reveals a unique architecture, provides mechanistic insight, and identifies ligand-binding determinants for PglC and the monotopic PGT superfamily.

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Conservation and Covariance in Small Bacterial Phosphoglycosyltransferases Identify the Functional Catalytic Core

Lukose

Luo

Kozakov

et al. 2015

Biochemistry

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Phosphoglycosyltransferases (PGTs) catalyze the transfer of a C1′-phosphosugar from a soluble sugar nucleotide diphosphate to a polyprenol-phosphate. These enzymes act at the membrane interface, forming the first membrane-associated intermediates in the biosynthesis of cell-surface glycans and glycoconjugates including glycoproteins, glycolipids and the peptidoglycan in bacteria. PGTs vary greatly in both in their membrane topologies and their substrate preferences. PGTs, such as MraY and WecA, are polytopic, while other families of uniquely prokaryotic enzymes have only a single predicted transmembrane helix. PglC, a PGT involved in the biosynthesis of N-linked glycoproteins in the enteropathogen C. jejuni, is representative of one of the structurally most simple members of the diverse family of small bacterial PGT enzymes. Herein, we apply bioinformatics and covariance-weighted distance constraints in geometry- and homology-based model building, together with mutational analysis to investigate monotopic PGTs. The pool of 15,000 sequences that are analyzed include the PglC-like enzymes, as well as sequences from two other related PGTs that contain a “PglC-like” domain embedded in their larger structures (namely, the bifunctional PglB family, typified by PglB from N. gonorrheae and WbaP-like enzymes, typified by WbaP from S. enterica). Including these two sub-families of PGTs in the analysis highlights key residues conserved across all three families of small bacterial PGTs. Mutagenesis analysis of these conserved residues provides further information on the essentiality of many of these residues in catalysis. Construction of a structural model of the cytosolic globular domain utilizing three-dimensional distance constraints, provided by conservation covariance analysis, provides additional insight into the catalytic core of these families of small bacterial PGT enzymes.

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Bacterial phosphoglycosyl transferases: initiators of glycan biosynthesis at the membrane interface

Lukose

Walvoort

Imperiali

2017

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Phosphoglycosyl transferases (PGTs) initiate the biosynthesis of both essential and virulence-associated bacterial glycoconjugates including lipopolysaccharide, peptidoglycan and glycoproteins. PGTs catalyze the transfer of a phosphosugar moiety from a nucleoside diphosphate sugar to a polyprenol phosphate, to form a membrane-bound polyprenol diphosphosugar product. PGTs are integral membrane proteins, which include between 1 and 11 predicted transmembrane domains. Despite this variation, common motifs have been identified in PGT families through bioinformatics and mutagenesis studies. Bacterial PGTs represent important antibacterial and virulence targets due to their significant role in initiating the biosynthesis of key bacterial glycoconjugates. Considerable effort has gone into mechanistic and inhibition studies for this class of enzymes, both of which depend on reliable, high-throughput assays for easy quantification of activity. This review summarizes recent advances made in the characterization of this challenging but important class of enzymes.

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Characterization of an NADH-Dependent Persulfide Reductase from Shewanella loihica PV-4: Implications for the Mechanism of Sulfur Respiration via FAD-Dependent Enzymes^,

et al. 2010

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The NADH-dependent persulfide reductase (Npsr), a recently discovered member of the PNDOR family of flavoproteins that contains both the canonical flavoprotein reductase domain and a rhodanese domain, is proposed to be involved in the dissimilatory reduction of S(0) for Shewanella loihica PV-4. We have previously shown that polysulfide is a substrate for this enzyme, and a recently determined structure of a closely related enzyme (CoADR-Rhod from Bacillus anthracis) suggested the importance of a bound coenzyme A in the mechanism. The work described here shows that the in vivo oxidizing substrates of Npsr are the persulfides of small thiols such as CoA and glutathione. C43S, C531S, and C43,531S mutants were created to determine the role of the flavoprotein domain cysteine (C43) and the rhodanese domain cysteine (C531) in the mechanism. The absolute requirement for C43 in persulfide or DTNB reductase activity shows that this residue is involved in S-S bond breakage. C531 contributes to, but is not required for, catalysis of DTNB reduction, while it is absolutely required for reduction of any persulfide substrates. Titrations of the enzyme with NADH, dithionite, titanium(III), or TCEP demonstrate the presence of a mixed-disulfide between C43 and a tightly bound CoA, and structures of the C43 and C43,531S mutants confirm that this coenzyme A remains tightly bound to the enzyme in the absence of a C43-CoA S-S bond. The structure of Npsr suggests a likely site for binding and reaction with the persulfide substrate on the rhodanese domain. On the basis of kinetic, titration, and structural data, a mechanism for the reduction of persulfides by Npsr is proposed.

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A Rapid and Efficient Luminescence-based Method for Assaying Phosphoglycosyltransferase Enzymes

Das

Walvoort

Lukose

et al. 2016

Sci Rep

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Phosphoglycosyltransferases (PGTs) are families of integral membrane proteins with intriguingly diverse architectures. These enzymes function to initiate many important biosynthetic pathways including those leading to peptidoglycan, N-linked glycoproteins and lipopolysaccharide O-antigen. In spite of tremendous efforts, characterization of these enzymes remains a challenge not only due to the inherent difficulties associated with the purification of integral membrane proteins but also due to the limited availability of convenient assays. Current PGT assays include radioactivity-based methods, which rely on liquid-liquid or solid-liquid extractions, multienzyme systems linked to lactate dehydrogenase and NAD+ generation, and HPLC-based approaches, all of which may suffer from low sensitivity and low throughput. Herein, we present the validation of a new luminescence-based assay (UMP-Glo) for measuring activities of PGT enzymes. This assay measures UMP, the by-product of PGT reactions, in a sensitive and quantitative manner by measuring the luminescence output in a discontinuous coupled assay system. The assay is rapid and robust in nature, and also compatible with microtiter plate formats. Activity and kinetic parameters of PglC, a PGT from Campylobacter jejuni, were quickly established using this assay. The efficacy of the assay was further corroborated using two different PGTs; PglC from Helicobacter pullorum and WecA from Thermatoga maritima.

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Vinita Lukose

Membrane association of monotopic phosphoglycosyl transferase underpins function

Conservation and Covariance in Small Bacterial Phosphoglycosyltransferases Identify the Functional Catalytic Core

Bacterial phosphoglycosyl transferases: initiators of glycan biosynthesis at the membrane interface

Characterization of an NADH-Dependent Persulfide Reductase from Shewanella loihica PV-4: Implications for the Mechanism of Sulfur Respiration via FAD-Dependent Enzymes^,

A Rapid and Efficient Luminescence-based Method for Assaying Phosphoglycosyltransferase Enzymes

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Vinita Lukose

Membrane association of monotopic phosphoglycosyl transferase underpins function

Conservation and Covariance in Small Bacterial Phosphoglycosyltransferases Identify the Functional Catalytic Core

Bacterial phosphoglycosyl transferases: initiators of glycan biosynthesis at the membrane interface

Characterization of an NADH-Dependent Persulfide Reductase from Shewanella loihica PV-4: Implications for the Mechanism of Sulfur Respiration via FAD-Dependent Enzymes,

A Rapid and Efficient Luminescence-based Method for Assaying Phosphoglycosyltransferase Enzymes

Contact Info

Product

Resources

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Characterization of an NADH-Dependent Persulfide Reductase from Shewanella loihica PV-4: Implications for the Mechanism of Sulfur Respiration via FAD-Dependent Enzymes^,